EP1911339A1 - Double disc plough with depth guide roller and energy storage - Google Patents

Abstract

The device has a pivot arm mounted about an axis transverse to the working direction (4) and at a distance from and in front of the pivot axis of the dual disk plow (1) so as to be pivotable in the horizontal direction. It has a connecting linkage between the pivot arm of the roller and supporting arm (6) of the plow that is flexible in the pressure direction that ensures parallel guidance of the plow by the depth guidance roller.

Description

The invention relates to a double disc coulter with depth control roller for seed drills according to the preamble of claim 1.

Such a double disc coulter is the European Patent 1,060,649 B1 refer to. In the subject matter is a double disc coulter with depth control role, which has large deviations of the seeding depth in uneven ground conditions, since when lowering or raising the management level of the depth control role, the seeding reduced or increased by only half the amount. Of a consistent depth control can not be spoken here. In addition, this version has the disadvantage that upon impact of the double disc coulter on a ground obstacle large forces in the area of the individual components occur, especially since the depth control role when dodging the Doppelscheibenschares must avoid up to twice the amount and thus extremely high acceleration forces can occur.

Also the Canadian registration CA 2023239 shows a double disc coulter with depth control roller for seed drills. In this embodiment, although due to the sprung connection of the depth control roller with the double disc coulter no high component loads occur when the double disc coulter encounters a ground obstacle, but is similar to the European Patent 1,060,649 B1 no precise depth guidance of the double disc coulters possible on uneven terrain, also due to the sprung mounting of the depth control roller with the double disc coulter. Depending on soil resistance and given coulter pressure the double disc coulter works deeper or shallower because the depth control roller gives way more or less due to the sprung connection with the double disc coulter.

From the DE-OS 103 52 209 a seed drill is known with the two pivot arms over a limited pivoting angle range without forced control relative to each other are pivotally connected forcibly controlled over this angle range addition to each other. Furthermore, the handlebar for the second coulter to be designed such that second and third pivot arms are connected via a limited pivot angle range without forced control relative to each other pivotally and forcibly controlled over this angle range addition to each other. The device shown there, however, occupies a very large amount of space, since when swinging the components to the rear, behind these components for sufficient space must be provided. The space required for this is at the expense of a desirable compactness of the device.

The object of the invention is to provide a double disc coulter with depth control roller for seed drills, which is compact and in which on the one hand precise depth control of Doppelscheibenschares is ensured even on uneven terrain and in which on the other hand it is ensured that upon impact of the double disc coulters a ground obstacle does not have to be excavated or accelerated up to the depth control roller.

This object is achieved by the features of the characterizing part of claim 1.

By providing a separate pivot arm for the depth control role, the double disc coulter is indeed performed by the depth control role in depth, but when hitting the double disc coulter on a ground obstacle but only deviates the double disc coulter, but not the depth control roller. With the present embodiment of the double disc coulter with depth control roller a kinematic Parallelogrammfohrung of Doppelscheibenschares is realized in a particularly suitable manner, so to speak. The transverse axis for the depth control roller is positioned in front of the double disc coulter, which allows pivoting in particular upwards. An annoying change in the position of the depth control roller during the pivoting process to the rear is thereby largely avoided. This allows a total of a compact design of the drill, since downstream components can be arranged extremely close behind the depth control rollers.

The invention further provides that the connecting link is formed upon impact of the double disc coulters on an obstacle a largely unobstructed avoidance of Doppelscheibenschares permitting. The Nachgebbarkeit the connecting link is so large that even with larger obstacles, the double disc coulter can easily roll over the obstacles without the depth control role must be carried. This prevents damage to the double disc coulter and adjacent components.

According to the invention it is provided that the connecting link is designed as a chain, articulated arm or rope. By providing a connecting link as a chain, articulated arm or rope a connecting link is provided in the simplest way, which can transmit large tensile forces and at the same time also includes a large Nachgebbarkeit.

The invention further provides that the connecting link has damping elements for the absorption of high tensile forces. If at large coulter pressure and high operating speed, the double disc coulter rolls over an obstacle and then swinging back, the connecting link larger tensile forces must be taken over because the depth control roller on the connecting link, the double disc coulter in the Depth leads. The provision of damping elements ensures that greater tractive forces are absorbed and so lighter and thus cost-effective connecting links can be used.

The invention further provides that the pivot axis of the support arm is located in front of the double disc coulter, at a distance from the bottom of more than half the diameter and less than the entire diameter of the double disc coulter. This makes it possible to provide a compact coulter frame with more than one row of double disc coulters. The double disc coulters as well as the depth guide rollers when crossing over an obstacle predominantly upwards and only slightly to the rear. Subordinate depth control rollers can therefore be provided immediately behind the double disc coulter; it is not necessary to provide additional clearance behind the double disc coulters.

The invention further provides that the connecting link is formed so that the upper connection point at a distance A to the transverse axis between the transverse axis and the axis of the depth control roller with the pivot arm of the depth control roller and the lower connection point at a distance B to the pivot axis between the pivot axis and the axis of the Doppelscheibenschares is arranged with the support arm and that the distance A to the distance B is approximately in the ratio as the distance C between the transverse axis and the axis of the depth control roller to the distance D between the pivot axis and the axis of the double disc coulter. By this gear technical arrangement is ensured by simple means that the depth control roller leads the double disc coulter exactly in depth. When the depth control roller is moved up or down on uneven terrain, the double disc coulter is changed by the same amount in its position. Thus, the default sowing depth remains the same.

It is further provided that the pivot axis of the double disc coulter and / or the transverse axis of the depth control roller is equipped with a maintenance-free joint with a rubber bearing.

Especially in seed drills with larger working widths far more than 50 coulters can be provided. If each coulter needs to be lubricated or serviced at regular intervals, this will be a relatively time consuming process for the operator. A maintenance-free joint offers considerable advantages and also cost reductions.

According to the invention it is further provided that both the pivot axis of the double disc coulter and the transverse axis of the depth control roller are equipped with maintenance-free joints with rubber bearings. If all the joints of the double disc coulter and the depth control roller are equipped with maintenance-free joints, the total maintenance required for a seed drill is further reduced. The maintenance-free joints can be correspondingly simple if they are equipped with rubber bearings or similar materials.

The invention further provides that the respective rubber bearing consists of an outer sleeve with a large inner diameter and an inner sleeve with a smaller outer diameter than the inner diameter of the outer sleeve and that the two sleeves are torsionally elastic connected by rubber or plastic material.

This rubber bearing design is very compact and easy to assemble. During assembly, for example, the outer sleeve is firmly clamped with the designated components of the coulter frame, the inner sleeve is firmly bolted to the support frame or with the swivel arm. As a result, a horizontal pivoting of the double disc coulter and the depth control roller is made possible only via the torsionally elastic rubber or plastic material. Wear of the components is throughout Joint area excluded. It is advantageous if this happens as possible without restoring force or restoring force, so that the energy generated by the energy storage coulter pressure is not affected as possible during the horizontal pivoting movements of the double disc coulter and the depth control roller. For larger restoring forces or negative restoring forces of the rubber bearings they would influence the preset coulter pressure and also the sinking depth of the depth control roller into the ground.

Figur 1

eine Seitenansicht der Aufhängung des Doppelscheibenschares und der Tiefenführungsrolle,

Figur 2

eine Seitenansicht des Doppelscheibenschares mit Tiefenführungsrolle,

Figur 3

eine andere Seitenansicht des Doppelscheibenschares mit Tiefenführungsrolle und

Figur 4

eine Seitenansicht des Doppelscheibenschares mit Tiefenführungsrolle und hydraulischem Energiespeicher.

Further details and advantages of the subject invention will become apparent from the following description and the accompanying drawings, in which an embodiment is shown with the necessary details and individual parts. Show it:

FIG. 1

a side view of the suspension of the double disc coulter and the depth control roller,

FIG. 2

a side view of the double disc coulter with depth control roller,

FIG. 3

another side view of the double disc coulter with depth control roller and

FIG. 4

a side view of the double disc coulter with depth control roller and hydraulic energy storage.

Figure 1 shows a side view of the suspension of the double disc coulter 1 and not shown in this figure depth control roller 2. The coulter frame 7, the carrier 25 is fixed, on the one hand, the transverse axis 9 of the pivot arm 8 and the other the pivot axis 5 of the support arm 6 of the double disc coulters receives. Both the pivot axis 5 and the transverse axis 9 are designed as maintenance-free joints 19 with rubber bearings 21. Each rubber bearing consists of an outer sleeve 22, an inner sleeve 23 and an interposed rubber or Plastic material 24, which connects the sleeves torsionally soft together. The connecting link 10 is pivotally connected to both the support arm 6 and the pivot arm 8. This will be discussed in more detail in the description of FIG. About the energy storage 3, in this case a spring 30, the support arm 6 is pressed with the double disc coulter 1 to the ground. The spring 30 is connected at its one end 31 to the spring suspension 32. The other end 33 of the spring 30 is connected to the wire rope 35, which is connected to the cross tube 34. The cross tube 34 is rotatably mounted on the coulter frame 7. By rotating the cross tube 34, the bias of the spring 30 is increased and also the co-compression of the double disc coulter 1. To ensure parallel guidance of the double disc coulter 1 in relation to the depth control roller 2, the connecting link 10 is in special connection with the pivot arm 8 of the depth control roller 2 and The support arm 6 of the double disc coulter 1. It will be discussed in more detail in the description of Figure 3.

Figure 2 shows a complete side view of the double disc coulter 1 with depth control roller 2. The depth control roller 2 with its axis 13 is seen arranged in the direction of work 4 behind the double disc coulter 1 and connected to the pivot arm 8. The double disc coulter 1 is connected with its axis 14 to the support arm 6. Both the double disc coulter 1 and the depth guide roller 2 are horizontally pivotally connected via the pivot axis 5 and the transverse axis 9 with the carrier 25 and above with the coulter frame 7. The connecting link 10 has the spring suspension 32 at the top and a slot 20 in the region of the upper connection point 11. The connecting link 10 is connected to the lower connection point 12 with the support arm 6 of the double disc coulter 1. When the double disc coulter 1 hits a ground obstacle, it deviates upwards. Here, the double disc coulter 1 is moved together with the connecting link 10 against the force of the energy storage device 3 and the spring 30 upwards, as far as it allows the slot 20. Only then would the depth control roller also move upwards. Also conceivable is the use of a Knucklenkers instead of the connecting link 10, which would then allow a greater evasive height of the double disc coulter 1. The same applies to the use of chains or ropes as connecting link 10, which would then also allow a large evasive height of the double disc coulter 1. The energy storage 3 would then have to be arranged adapted for transmission technology.

Figure 3 shows a further side view of the double disc coulter 1 with depth control roller 2. It illustrates in particular the gearbox arrangement of the connecting link 10, the pivot arm 8 and the support arm 6. To ensure accurate parallel guidance of the double disc coulter 1 in relation to the depth control roller 2, the connecting link 10 was with the upper connection point 11 at a distance A to the transverse axis 9 with the pivot arm 8 of the depth control roller 2 and connected to the lower connection point 12 at a distance B to the pivot axis 5 with the support arm 6 of the double disc coulter 1. The distance A to the distance B is approximately in the same ratio as the distance C between the transverse axis 9 and the axis 13 of the depth control roller 2 to the distance D between the pivot axis 5 and the axis 14 of the double disc coulter. 1

Figure 4 shows an embodiment of the double disc coulter 1 with depth control roller 2 and hydraulic energy storage. The hydraulic energy storage consists of a cross tube, not shown, which has a pressure chamber with a plurality of juxtaposed piston rod guides 41. The lateral distance of the individual piston rod guides 41 corresponds to the row spacing of the double disc coulters 1 to each other. The piston rod guides 41 respectively receive piston rods 42, which are designed as plunger 43. The plunger 43 are based on ram 44 and the hinge connection 45 directly on the pivot arm 6 of the double disc coulter 1 from. As a connecting link 10, a cable 38 is provided here. The plunger 44 has approximately in the middle of a buffer 48, which serves as a damping element. The pivot arm 8 has a stop 50. With a corresponding deflection of the support arm 6, the buffer 48 abuts against the Stop 50 and prevents so that the plunger 43 is pushed too far into the piston rod guide 41. The pivot axis 9 is arranged in front of the double disc coulter 1 and thus ensures the pivoting of the swivel arm 8 with depth control roller 2 upwards.

Claims (9)

1. Double disc coulter (1) with depth control roller (2) for seed drills, in which the pressure of the double disc coulter (1) on the ground by an energy storage device (3) is supported, wherein the double disc coulter (1) arranged transversely to the working direction (4) Pivot axis (5) pivotally connected in the horizontal direction by means of support arm (6) with the share frame (7) of the seed drill and is guided over the depth control roller (2) in the working depth,
characterized,
that the depth guide roller (2) has a pivoting arm (8) which is arranged about a transversely to the working direction (4) and at a distance from the pivot axis (5) of the double disc coulter (1) and in front of the double disc coulter (1) lying transverse axis (9) in is mounted pivotably in the horizontal direction and that between the pivot arm (8) of the depth control roller (2) and the support arm (6) of the double disc coulter (1) a yielding formed in the pressure direction connecting link (10) is provided, the gear technically an approximately parallel guidance of Doppelscheibenschares ( 1) ensured by the depth control roller (2). 2. double disc coulter according to claim 1,
characterized,
that the connecting link (10) on impact of the double disc coulter (1) on an obstacle a largely unobstructed evasion of the double disc coulter (1) is permitting. 3. double disc coulter according to claim 1,
characterized,
that the connecting link (10) as a chain, articulated arm or rope (38) is formed. 4. double disc coulter according to claim 1,
characterized,
in that the connecting link (10, 38) has damping elements for absorbing large tractive forces. 5. double disc coulter according to claim 1,
characterized,
that the pivot axis (5) of the support arm (6) in front of the double disc coulter (1), at a distance from the bottom of more than half the diameter and less than the entire diameter of the double disc coulter (1). 6. double disc coulter according to claim 1,
characterized,
in that the connecting link (10) is formed such that the upper connection point (11) is spaced at a distance A from the transverse axis (9) between the axis (13) of the depth guide roller (2) and the pivoting arm (8) Depth guide roller (2) and the lower connection point (12) at a distance B to the pivot axis (5) between the pivot axis (5) and the axis (14) of the double disc coulter (1) with the support arm (6) is arranged and that the distance A to the distance B is approximately in the ratio as the distance C between the transverse axis (9) and the axis (13) of the depth control roller (2) to the distance D between the pivot axis (5) and the axis (14) of the double disc coulter (1). 8. double disc coulter according to at least one of the preceding claims,
characterized,
that the pivot axis (5) of the double disc coulter (1) and / or the transverse axis (9) of the depth control roller is equipped with a maintenance-free joint (19) with a rubber bearing (21). 9. double disc coulter according to at least one of the preceding claims,
characterized,
that both the pivot axis (5) of the double disc coulter (1) and the transverse axis (9) of the depth control roller (2) with maintenance-free joints (19) with rubber bearings (21) are equipped. 10. double disc coulter according to at least one of the preceding claims,
characterized,
in that the respective rubber bearing (21) consists of an outer sleeve (22) with a large inner diameter and an inner sleeve (23) with a smaller outer diameter than the inner diameter of the outer sleeve (22) and that the two sleeves (22) and (23) by means of rubber or plastic material (24) are torsionally elastic connected to each other.

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